Display device

ABSTRACT

A display device includes a first color pixel, a second color pixel neighboring the first color pixel in a first direction, a third color pixel neighboring the second color pixel in the first direction, a fourth color pixel neighboring the first color pixel in a second direction, a fifth color pixel neighboring the second color pixel in the second direction, and a sixth color pixel neighboring the third color pixel in the second direction, wherein each of the first color pixel, the second color pixel, the fourth color pixel and the fifth color pixel has a first long-side length, the third color pixel has a second long-side length which is greater than the first long-side length, and the sixth color pixel has a third long-side length which is less than the first long-side length.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. application Ser. No.14/516,858, filed Oct. 17, 2014, which is based upon and claims thebenefit of priority from Japanese Patent Application No. 2013-217441,filed Oct. 13, 2013, the entire contents of which are incorporatedherein by reference.

FIELD

Embodiments described herein relate generally to a display device.

BACKGROUND

In recent years, in color display devices, methods for improving displayluminance have been proposed. As an example, there has been proposed aliquid crystal display device in which one unit pixel is constituted byarranging a red (R) pixel, a green (G) pixel, a blue (B) pixel and awhite (W) pixel in a row direction in a predetermined order.

The white pixel has a higher efficiency of use of light than the redpixel, green pixel and blue pixel, and the transmittance of the whitepixel is about three times higher than the transmittance of each of thered pixel, green pixel and blue pixel. Thus, the area of the white pixelor the maximum value of the amount of transmissive light in the whitepixel is not freely determined, but needs to be set in consideration ofcolor reproducibility, etc. For example, the display luminance of thewhite pixel needs to be so set as to become a value lower than the totalluminance of the red pixel, green pixel and blue pixel. Specifically, ina case where only the white pixel is enlarged, the display luminance isenhanced, but the color reproducibility deteriorates. In addition, thearea of each of the red pixel, green pixel and blue pixel is sacrificedby an amount corresponding to the enlargement of the white pixel in theunit pixel of the limited area, and as a result the large white pixelcannot effectively be utilized.

Furthermore, in the case where the size of the white pixel has beenenlarged, when an image with a high display luminance in the white pixelis displayed, the white pixel tends to be easily visually recognised,and consequently a displayed image tends to be visually recognized as arough image.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a view which schematically illustrates a structure and anequivalent circuit of a crystal display panel LPN which constitutes adisplay device according to an embodiment.

FIG. 2 is a plan view which schematically illustrates a structureexample of one pixel PX of an array substrate AR which is applicable tothe display device of the embodiment.

FIG. 3 is a plan view which schematically illustrates a structureexample of one pixel PX of a counter-substrate CT which is applicable tothe display device of the embodiment.

FIG. 4 is a view which schematically illustrates a cross-sectionalstructure of the liquid crystal display panel LPN in an active areaincluding a switching element SW shown in FIG. 2.

FIG. 5 is a plan view which schematically illustrates an example of alayout of pixels and color filters in the embodiment.

FIG. 6 is a plan view which schematically illustrates a structureexample of an array substrate AR to which the color filters shown inFIG. 5 are applied.

FIG. 7 is a plan view which schematically illustrates a structureexample of a second common electrode CE2 which is disposed to be opposedto the array substrate AR shown in FIG. 6.

FIG. 8 is a plan view which schematically illustrates another structureexample of the array substrate AR which is applicable to the displaydevice of the embodiment.

FIG. 9 is a plan view which schematically illustrates another structureexample of the array substrate AR which is applicable to the displaydevice of the embodiment.

DETAILED DESCRIPTION

In general, according to one embodiment, a display device includes: afirst color pixel; a second color pixel which is a pixel of a colordifferent from a color of the first color pixel, and neighbors the firstcolor pixel is a first direction; a third color pixel which is a pixelof a color different from the color of the first color pixel and thecolor of the second color pixel, and neighbors the second color pixel inthe first direction; a fourth color pixel which is a pixel of the samecolor as the first color pixel, and neighbors the first color pixel in asecond direction; a fifth color pixel which, is a pixel of the samecolor as the second color pixel, and neighbors the second color pixel inthe second direction; and a sixth color pixel which is a pixel of acolor different from the colors of the first color pixel, the secondcolor pixel and the third color pixel, and neighbors the third colorpixel in the second direction, wherein each of the first color pixel,the second color pixel, the fourth color pixel and the fifth color pixelhas a first long-side length in the second direction, the third colorpixel has a second long-side length in the second direction, which isgreater than the first long-side length, and the sixth color pixel has athird long-side length in the second direction, which is less than thefirst long-side length.

According to another embodiment, a display-device includes: a firstsubstrate including a first pixel electrode, a second pixel electrodeneighboring the first pixel electrode in a first direction, a thirdpixel electrode neighboring the second pixel electrode in the firstdirection, a fourth pixel electrode neighboring the first pixelelectrode in a second direction, a fifth pixel electrode neighboring thesecond pixel electrode in the second direction, and a sixth pixelelectrode neighboring the third pixel electrode in the second direction;a second substrate including a first color filter extending in thesecond direction and opposed to the first pixel electrode and the fourthpixel electrode, a second color filter neighboring the first colorfilter in the first direction, extending in the second direction andopposed to the second pixel electrode and the fifth pixel electrode, athird color filter neighboring the second color filter in the firstdirection and opposed to the third pixel electrode, and a fourth colorfilter neighboring the third color filter in the second direction andopposed to the sixth pixel electrode; and a liquid crystal layer heldbetween the first substrate and the second substrate, wherein each ofthe first pixel electrode, the second pixel electrode, the fourth pixelelectrode and the fifth pixel electrode has a first long-side length inthe second direction, the third pixel electrode has a second long-sidelength in the second direction, which is greater than the firstlong-side length, and the sixth pixel electrode has a third long-sidelength in the second direction, which is less than the first long-sidelength.

Embodiments will now be described in detail with reference to theaccompanying drawings. In the drawings, structural elements having thesame or similar functions are denoted by like reference numerals, and anoverlapping description is omitted.

FIG. 1 is a view which schematically shows a structure and an equivalentcircuit of a liquid crystal display panel LPN which constitutes adisplay device according to an embodiment.

Specifically, the display device includes an active-matrix-type liquidcrystal display panel LPN. The liquid crystal display panel LPN includesan array substrate AR which is a first substrate, a counter-substrate CTwhich is a second substrate that is disposed to be opposed to the arraysubstrate AR, and a liquid crystal layer LQ which is held between thearray substrate AR and the counter-substrate CT. The liquid crystaldisplay panel LPN includes an active area ACT which displays an image.The active area ACT corresponds to a region where the liquid crystallayer LQ is held between the array substrate AR and thecounter-substrate CT, has a rectangular shape, for instance, and iscomposed of a plurality of pixels PX which are arrayed in a matrix.

The array substrate AR includes, in the active area ACT, a plurality ofgate lines G (G1 to Gn) extending in a first direction X, a plurality ofsource lines S (S1 to Sm) extending in a second direction Y crossing thefirst direction X, a switching element SW which is electricallyconnected to the gate line G and source line S in each pixel PX, a pixelelectrode PE which is electrically connected to the switching element SWin each pixel PX, and a first common electrode CE1 which is opposed tothe pixel electrode PE. A storage capacitor CS is formed, for example,between the first common electrode CE1 and the pixel electrode PE.

On the other hand, the counter-substrate CT includes a second commonelectrode CE2 which is opposed to the pixel electrode PE via the liquidcrystal layer LQ.

Each of the gate lines G is led out to the outside of the active areaACT and is connected to a first driving circuit GD. Each of the sourcelines S is led out to the outside of the active area ACT and isconnected to a second driving circuit SD. At least parts of the firstdriving circuit GD and second driving circuit SD are formed on, forexample, the array substrate AR, and are connected to a driving IC chip2. The driving IC chip 2 incorporates a controller which controls thefirst driving circuit GD and second driving circuit SD, and functions asa signal supply source for supplying necessary signals for driving theliquid crystal display panel LPN. In the example illustrated, thedriving IC chip 2 is mounted on the array substrate AR, on the outsideof the active area ACT of the liquid crystal display panel LPN.

The first common electrode CE1 and second common electrode CE2 have thesame potential, and each of them extends over substantially the entiretyof the active area ACT and is formed commonly over a plurality of pixelsPX. The first common electrode CE1 and second common electrode CE2 areled out to the outside of the active area ACT and are connected to apower supply module Vcom. The power supply module Vcom is formed, forexample, on the array substrate AR on the outside of the active areaACT, and is electrically connected to the first common electrode CE1 andalso electrically connected to the second common electrode CE2 via anelectrically conductive member (not shown). At the power supply moduleVcom, for example, a common potential, is supplied to the first commonelectrode CE1 and second common electrode CE2.

FIG. 2 is a plan view which schematically shows a structure example ofone pixel PX of the array substrate AR which is applicable to thedisplay device of the embodiment.

The array substrate AR includes a gate line G1, a source line S1, asource line S2, a switching element SW, a first common electrode CE1,and a pixel electrode PE. In the example illustrated, as indicated by abroken line in FIG. 2, the pixel PX has a rectangular shape with a pairof short sides parallel to the first direction X, and a pair of longsides parallel to the second direction Y.

The gate line G1 extends linearly in the first direction X. The sourceline S1 and source line S2 are disposed with a distance in the firstdirection X, and extend linearly in the second direction Y,respectively. The length of the pixel PX in the first direction X issubstantially equal to the pitch of neighboring source lines in thefirst direction X. The length of the pixel PX in the second direction Yis substantially equal to the pitch of neighboring gate lines in thesecond direction Y.

In the pixel PX illustrated, the source line S1 is located at a leftside end portion, and is disposed to extend over a boundary between thepixel PX and a pixel neighboring on the left side. The source line S2 islocated at a right side end portion, and is disposed to extend over aboundary between the pixel PX and a pixel neighboring on the right side.The gate line G1 is disposed in a manner to cross a central portion ofthe pixel PX. In the present embodiment, as illustrated, there is nostorage capacitance line which crosses the pixel PX for forming astorage capacitance CS.

The switching element SW is composed of, for example, an n-channelthin-film transistor (TFT). Although a detailed illustration is omitted,the switching element SW includes a semiconductor layer of, e.g.polysilicon, a gate electrode connected to the gate line G1, a sourceelectrode which is connected to the source line S1 and is put in contactwith the semiconductor layer, and a drain electrode WD which is incontact with the semiconductor layer.

As indicated by lower-right hatching lines in the Figure, the firstcommon electrode CE1 is disposed over substantially the entirety of thepixel PX, and further extends from the pixel PX beyond the source lineS1 and source line S2 in the first direction X and extends in the seconddirection Y. Specifically, the first common electrode CE1 is opposed tothe source line S1 and source line S2 and is formed continuously overpixels neighboring the pixel PX in the first direction X. In addition,the first common electrode CE1 is formed continuously over pixelsneighboring the pixel PX in the second direction Y. Furthermore,although not described in detail, the first common electrode CE1 isdisposed over substantially the entirety of the active area whichdisplays an image, and a part thereof is led out to the outside of theactive, area and electrically connected to the power supply module, asdescribed above. It should be noted, however, that an opening OP forexposing the drain electrode WD is formed in the first common electrodeCE1.

In the meantime, the first common electrode CE1 may be formed such that,while the first common electrode CE1 is disposed over substantially theentirety of the pixel PX, the first common electrode CE1 is madediscontinuous at an area overlapping the gate line G1, the first commonelectrode CE1 extends from the pixel PX over the source line S1 andsource line S2 in the first direction X, the first common electrode CE1is opposed to the source line S1 and source line S2, and the firstcommon electrode CE1 is continuously formed in a strip shape over pixelsneighboring the pixel PX in the first direction X. In this case, too,the first common electrode CE1 is led out to the outside of the activearea which displays an image, and is electrically connected to the powersupply module, as described above.

As indicated by upper-right hatching lines in the Figure, the pixelelectrode PE is formed in an island shape in the pixel PX, and isopposed to the first common electrode CE1. Incidentally, in the exampleillustrated, although only the pixel electrode PE disposer in the pixelPX is depicted, pixel electrodes are also disposed in other pixelsneighboring the pixel PX in the first direction X and second directionY. The pixel electrode PE is electrically connected to the drainelectrode WD of the switching element SW via a contact hole CH. Theshape of the pixel electrode PE illustrated corresponds to, for example,the shape of the pixel PX, and is a rectangular shape having a lesslength in the first direction X than in the second direction Y. Thecontact hole CH is located at a substantially central part of the pixelelectrode PE. Incidentally, a part of the pixel electrode PE may extendto positions overlapping the source line S1 and source line S2.

In the present embodiment, the structure of each pixel of the activearea is identical to the above-described structure example. However, theactive area includes pixels of different pixel sizes, i.e. differentlengths in the first direction X and second direction Y.

FIG. 3 is a plan view which schematically shows a structure example ofone pixel PX of the counter-substrate CT which is applicable to thedisplay device of the embodiment. FIG. 3 shows only structural partsthat, are necessary for the description, and the source line S1, sourceline S2, gate line G1, and pixel electrode PE, which are main parts ofthe array substrate, are indicated by broken lines, and the depiction ofthe first common electrode is omitted.

The counter-substrate CT includes a second common electrode CE2. Thesecond common electrode is disposed in the pixel PX, and is opposed tothe pixel electrode PE. In addition, the second common electrode CE2extends from the pixel PX in the first direction X and the seconddirection Y, and is located also above the source line S1 and sourceline S2. Specifically, although not described in detail, the secondcommon electrode CE2 is disposed continuously over pixels neighboring onthe right side and left side along the first direction X of the pixelPX, and pixels neighboring on the upper side and lower side along thesecond direction Y of the pixel PX. Furthermore, although not describedin detail, the second common electrode CE2 is disposed over almost theentirety of the active area.

A slit SL is formed in the second common electrode CE2 at a positionopposed to the pixel electrode PE. In the example illustrated, the slitSL is formed in a strip shape extending in the second direction Y, andis located substantially at a central part of the pixel PX. This slit SLcorresponds to an alignment control member which mainly controls thealignment of liquid crystal molecules. In the meantime, instead of theslit, some other alignment control member, such as a projection stackedon the second common electrode CE2, may be disposed, if such analignment control member has a function of controlling the alignment ofliquid crystal molecules. In addition, the shape of the slit SL is notlimited to the example illustrated, and may be, for instance, a crossshape.

FIG. 4 is a view which schematically illustrates a cross-sectionalstructure of the liquid crystal display panel LPN in the active areaincluding the switching element SW shown in FIG. 2.

The array substrate AR is formed by using a first insulative substrate10 having light transmissivity, such as a glass substrate or a resinsubstrate. The array substrate AR includes, on that side of the firstinsulative substrate 10, which is opposed to the counter-substrate CT, aswitching element SW, a first, common electrode CE1, a pixel electrodePE, a first insulation film 11, a second insulation film 12, a thirdinsulation film 13, a fourth insulation film 14, and a first verticalalignment film AL1.

In the example illustrated, the switching element SW is a thin-filmtransistor of a top gate type. The switching element SW includes asemiconductor layer SC which is disposed on the first insulativesubstrate 10. In the meantime, an undercoat layer, which is aninsulation film, may be interposed between the first insulativesubstrate 10 and the semiconductor layer SC. The semiconductor layer SCis covered with the first insulation film 11. The first insulation film11 is also disposed on the first insulative substrate 10. This firstinsulation film 11 is formed of, for example, an inorganic material,such as silicon nitride.

A gate electrode WG of the switching element SW is formed on the firstinsulation film 11, and is located immediately above the semiconductorlayer SC. The gate electrode WG is electrically connected to the gate,line G1 (or formed integral with the gate line G1) and is covered withthe second insulation film 12. The second insulation film 12 is alsodisposed on the first insulation film 11. This second insulation film 12is formed of, for example, an inorganic material such astetraethoxysilane (TEOS).

A source electrode WS and a drain electrode WD of the switching elementSW are formed on the second insulation film 12. The source line S1 andsource line S2 are similarly formed on the second insulation film 12.The source electrode WS illustrated is electrically connected to thesource line S1 (or formed integral with the source line S1). The sourceelectrode WS and drain electrode WD are put in contact with thesemiconductor layer SC via contact holes, penetrating the firstinsulation film 11 and second insulation film 12. The switching elementSW with this structure, as well as the source line S1 and source lineS2, is covered with the third insulation film 13. The third insulationfilm 13 is also disposed on the second insulation film 12. This thirdinsulation film 13 is formed of, for example, a transparent resinmaterial.

The first common electrode CE1 extends over the third insulation film13. As illustrated in the Figure, the first common electrode CE1 coversthe upper side of the source line S1 and source line S2, and extendstoward neighboring pixels. The first common electrode CE1 is formed of atransparent, electrically conductive material such as indium tin oxide(ITO) or indium sine oxide (IZO). The fourth insulation film 14 isdisposed on the first common electrode CE1. A contact hole CH, whichpenetrates to the drain electrode WD, is formed in the third insulationfilm 13 and fourth insulation film 14. The fourth insulation film 14 hasa less thickness than the third insulation film 13, and is formed of,for example, an inorganic material such as silicon nitride. The fourthinsulation film 14 corresponds to an inter-layer insulation film whichcovers the first common electrode CE1.

The pixel electrode PE is formed in an island shape on the fourthinsulation film 14 and is opposed to the first common electrode CE1. Thepixel electrode PE is electrically connected to the drain electrode WDof the switching element SW via the contact hole CH. This pixelelectrode PE is formed of a transparent, electrically conductivematerial such as ITO or IZO. The pixel electrode PE is covered with thefirst vertical alignment film AL1.

On the other hand, the counter-substrate CT is formed by using a secondinsulative substrate 30 with light transmissivity, such as a glasssubstrate or a resin substrate. The counter-substrate CT includes, onthat side of the second insulative substrate 30, which is opposed to thearray substrate AR, a light-shield layer 31, color filters 32, anovercoat layer 33, a second common electrode CE2, and a second verticalalignment film AL2.

The light-shield layer 31 partitions each pixel PX in the active areaACT, and forms an aperture portion AP. The light-shield layer 31 isprovided at boundaries between color pixels, or at positions opposed tothe source lines provided on the array substrate AR. The light-shieldlayer 31 is formed of a light-shielding metallic material or a blackresin material.

The color filter 32 is formed in the aperture portion AP, and a partthereof overlaps the light-shield layer 31. The color filters 32 includea red color filter formed of a resin material which is colored in red, agreen color filter formed of a resin material which is colored in green,and a blue color filter formed of a resin material which is colored inblue. The red color filter is disposed in a red pixel which displaysred, the green color filter is disposed in a green pixel which displaysgreen, and the blue color filter is disposed in a blue pixel whichdisplays blue. In addition, a white Cox transparent) color-filter isdisposed in a white pixel which displays white. Incidentally, no colorfilter may be disposed in the white pixel. Besides, the white colorfilter may not strictly be an achromatic color filter, and may be acolor filter which is lightly colored (e.g. colored in light yellow).Boundaries between the color filters 32 of different colors are locatedat positions overlapping the light-shield layer 31 above the sourcelines S.

The overcoat layer 33 covers the color filters 32. The overcoat layer 33planarizes asperities of the light-shield layer 31 and color filters 32.The overcoat layer 33 is formed of, for example, a transparent resinmaterial. This overcoat layer 33 serves as an underlayer of the secondcommon electrode CE2.

The second common electrode CE2 is formed on that side of the overcoatlayer 33, which is opposed to the array substrate AR. As illustrated inthe Figure, the second common electrode CE2 extends above the sourceline S1 and source line S2, and extends toward the neighboring pixels.The second common electrode CE2 is formed of, for example, atransparent, electrically conductive material such as ITO or IZO. Thesecond common electrode CE2 is covered with the second verticalalignment film AL2.

The first vertical alignment film AL1 and second vertical alignment filmAL2 are formed of a material which exhibits vertical alignmentproperties, and have an alignment restriction force which aligns liquidcrystal molecules in a normal direction of the substrate, withoutrequiring alignment treatment such as rubbing.

The above-described array substrate AR and counter-substrate CT aredisposed such that their first vertical alignment film AL1 and secondvertical alignment film AL2 are opposed to each other. In this case, apredetermined cell gap is created between the array substrate AR and thecounter-substrate CT by columnar spacers which are formed on one of thearray substrate AR and counter-substrate CT. The array substrate AR andcounter-substrate CT are attached by a sealant in the state in which thecell gap is created. The liquid crystal layer LQ is sealed between thefirst vertical alignment film AL1 and second vertical alignment filmAL2. This liquid crystal layer LQ is composed of a liquid crystalcomposition with a negative dielectric constant anisotropy(negative-type).

A backlight unit BL is disposed on the back side of the liquid crystaldisplay panel LPN having the above-described structure. Various modesare applicable to the backlight unit BL, but a description of thedetailed structure of the backlight unit BL is omitted here.

A first optical element OD1 including a first, polarizer PL1 is disposedon an outer surface 10B of the first insulative substrate 10. A secondoptical element OD2 including a second polarizer PL2 is disposed on anouter surface 30B of the second insulative substrate 30. The firstpolarizer PL1 and second polarizer PL2 are disposed, for example, in apositional relationship of crossed Nicols in which their polarizationaxes are perpendicular to each other.

FIG. 5 is a plan view which schematically illustrates an example of alayout of pixels and color filters in the embodiment. In this example,the first direction X and second direction Y are perpendicular to eachother.

A unit pixel for realizing color display is composed of a plurality ofdifferent color pixels. The unit pixel is a minimum unit whichconstitutes a color image that is displayed on the active area. In thisexample, two unit pixels, namely a unit pixel UP1 and a unit pixel UP2,which are arranged in the first direction X, are illustrated. Each ofthe unit pixel UP1 and unit pixel UP2 is composed of six color pixels.

The unit pixel UP1 is composed of a color pixel (first color pixel)PX11, a color pixel (second color pixel) PX12, a color pixel (thirdcolor pixel) PX13, a color pixel (fourth color pixel) PX14, a colorpixel (fifth color pixel) BK15 and a color pixel (sixth color pixel)PX16. In the Figure, each color pixel, has a rectangular shape with apair of short sides in the first direction X, and a pair of long sidesin the second direction Y, and each color pixel is indicated by aone-dot-and-dash line. The color pixel PX12 is a pixel of a colordifferent from the color of the color pixel PX11 and neighbors the colorpixel PX11 in the first direction X. The color pixel PX13 is a pixel ofa color different from the colors of the color pixel PX11 and colorpixel PX12 and neighbors the color pixel PX12 in the first direction X.The color pixel PX14 is a pixel of the same color as the color pixelPX11 and neighbors the color pixel PX11 in the second direction Y. Thecolor pixel PX15 is a pixel of the same color as the color pixel PX12and neighbors the color pixel PX12 in the second direction Y. The colorpixel PX16 is a pixel of a color different from the colors of the colorpixel PX11, color pixel PX12 and color pixel PX13, and neighbors thecolor pixel PX13 in the second direction Y.

In this example, the color pixel PX11 and color pixel PX14 are redpixels, the color pixel PX12 and color pixel PX15 are green pixels, thecolor pixel PX13 is a blue pixel, and the color pixel PX16 is a whitepixel.

Each of the color pixel PX11, color pixel PX12, color pixel PX14 andcolor pixel PX15 has a long-side length L1 in the second direction Y.The color pixel PX13 has a long-side length L2 in the second directionY, which is greater than the long-side length L1. The color pixel PX16has a long-side length L3 in the second direction Y, which is less thanthe long-side length L1.

Each of the color pixel PX11, color pixel PX12, color pixel PX14 andcolor pixel PX15 has a short-side length S1 in the first direction X.Each of the color pixel PX13 and color pixel PX16 has a secondshort-side length S2 in the first direction X, which is greater than theshort-side length S1.

In this structure, the color pixel PX11, color pixel PX12, color pixelPX14 and color pixel PX15 are substantially equal in area. The colorpixel PX13 has a larger area than the color pixel PX 16. In addition,the area of the color pixel PX13 is greater than the area of the colorpixel PX11, etc., and is largest in the unit pixel UP1. The area of thecolor pixel PX16 is less than the area of the color pixel PX11, etc.,and is smallest in the unit pixel UP1.

A set of the color pixel PX13 and color pixel PX16 is displaced in thesecond direction Y from a set of the color pixel PX12 and color pixelPX15. In the example illustrated, the set of the color pixel PX13 andcolor pixel PX16 is displaced to the upper side in the Figure, relativeto the set of the color pixel PX12 and color pixel PX15. Specifically,the short side of the color pixel PX11 and the short side of the colorpixel PX12 extend on the same straight line which is parallel to thefirst direction X, but the short side of the color pixel PX13 extends onan outside in the second direction from each of the short sides of thecolor pixel PX11 and color pixel PX12. In addition, the short side ofthe color pixel PX14 and the short side of the color pixel PX15 extendon the same straight line which is parallel to the first direction X,but the short side of the color pixel PX16 extends on an inside in thesecond direction from each of the short sides of the color pixel PX14and color pixel PX15. In other words, the color pixel PX13 is enlargedto both the upper side and lower side in the Figure in the seconddirection Y, compared to the color pixel PX12, and the color pixel PX16is reduced in the second direction Y, compared to the color pixel PX15.

The unit pixel UP2 has a configuration which is similar to theconfiguration of the unit pixel UP1, but the unit pixel UP2 is differentfrom the unit pixel UP1 in that the white pixel and the blue pixel aretransposed. Specifically, the unit pixel UP2 is composed of a colorpixel PX21, a color pixel PX22, a color pixel PX23, a color pixel PX24,a color pixel PX25 and a color pixel PX26. The color pixel PX21 andcolor pixel PX24 are red pixels, the color pixel PX22 and color pixelPX25 are green pixels, the color pixel PX23 is a white pixel, and thecolor pixel PX26 is a blue pixel.

Specifically, in the unit pixel UP1 and unit pixel UP2 arranged in thefirst direction X, the color pixel PX13 and color pixel PX26, which areblue pixels, are located at positions displaced from a same straightline in the first direction X. In addition, the color pixel PX16 andcolor pixel PX23, which are white pixels, are located at positionsdisplaced from a same straight line in the first direction X.

Light-shield layers 31 are disposed at boundaries of the respectivecolor pixels. Each light-shield layer 31 extends linearly in the seconddirection Y. Incidentally, no light-shield layer 31 is disposed at aboundary between color pixels, of the same color. Specifically, nolight-shield layer 31 is disposed at a boundary between the color pixelPX11 and color pixel PX14, or between the color pixel PX12 and colorpixel PX15. The light-shield layer 31 is disposed at a boundary betweencolor pixels of different colors. Specifically, the light-shield layer31 extending linearly in the first direction X is disposed at a boundarybetween the color pixel PX13 and color pixel PX16. Thus, each of thecolor pixel PX13 and color pixel PX16 is surrounded by the light-shieldlayers 31.

A color filter (first color filter) 32R is formed in a strip shapeextending in the second direction Y, A color filter (second colorfilter) 32G neighbors the color filter 32R in the first direction X, andis formed in a strip shape extending in the second direction Y. A colorfilter (third color filter) 32B neighbors the color filter 32G in thefirst direction X, and is formed in an island shape. A color filter(fourth color filter) 32W neighbors the color filter 32B in the seconddirection Y, neighbors the color filter 32G in the first direction X,and is formed in an island shape. The color filter 32B and color filter32W are alternately disposed in the second direction Y.

The color filter 32R is disposed to correspond to the color pixels PX11and color pixel PX14 of the unit pixel UP1, and is disposed tocorrespond to the color pixels PX21 and color pixel PX24 of the unitpixel UP2. The color filter 32G is disposed to correspond to the colorpixels PX12 and color pixel PX15 of the unit pixel UP1, and is disposedto correspond to the color pixels PX22 and color pixel PX25 of the unitpixel UP2. The color filter 32B is disposed to correspond to the colorpixel PX13 of the unit pixel UP1, and is disposed to correspond to thecolor pixel PX26 of the unit pixel UP2. The color filter 32W is disposedto correspond to the color pixel PX16 of the unit pixel UP1, and isdisposed to correspond to the color pixels PX23 of the unit pixel UP2.

The color filter 32R and color filter 32G have an equal width in thefirst direction X. The color filter 32B and color filter 32W have anequal width in the first direction X, and this width is greater than thewidth of the color filter 32R, etc.

The color filter 32R is a red (R) color filter. The color filter 32G isa green (G) color filter. The color filter 32B is a blue (B) colorfilter. The color filter 32W is a white (W) color filter. The first tofourth color filters have mutually neighboring end portions overlappingthe light-shield layers 31.

In this manner, the active area includes the color pixels of the fourcolors (red pixels, green pixels, blue pixels, and white pixels), andthe number of color pixels of two colors (in the illustrated example,blue pixels and white pixels) of the four colors is half the number ofcolor pixels of the other two colors (in the illustrated example, redpixels and green pixels). In addition, the long-side length of the colorpixels, the number of which is smaller, is different from the long-sidelength of the color pixels, the number of which is larger. Furthermore,the short-side length of the color pixels, the number of which issmaller, is different from the short-side length of the color pixels,the number of which is larger.

For example, the sum of the areas of the color pixel PX11 and colorpixel PX14, which are the red pixels, is equal to the sum of the areasof the color pixel PX12 and color pixel PX15, which are the greenpixels, and is equal to the area of the color pixel PX13 which is theblue pixel. However, the area of each color pixel may be varied byaltering the long-side length and short-side length of the color pixelin accordance with the transmittance of each of the color filter 32Rwhich is applied to the red pixel, the color filter 32G which is appliedto the green pixel, and the color filter 32B which is applied to theblue pixel. In the case where the transmittance of the color filter B ishigher than the transmittance of the color filter 32R and color filter32G, the area of the color pixel PX13 may be made smaller than the sumof the areas of the color pixel PX11 and color pixel PX14 which are thered pixels.

FIG. 6 is a plan view which schematically illustrates a structureexample of an array substrate AR to which the color filters shown inFIG. 5 are applied. In this example, only the structure of the arraysubstrate AR, which is necessary for the description, is illustrated,and depiction of the first common electrode, etc. is omitted.

A gate line G1 extends in the first direction X and crosses centralportions of the color pixel PX11, color pixel PX12, color pixel PX13,color pixel PX21, color pixel PX22 and color pixel PX23. A gate line G2extends in the first direction X and crosses central portions of thecolor pixel PX14, color pixel PX15, color pixel PX16, color pixel PX24,color pixel PX25 and color pixel PX26.

A pixel electrode (first pixel electrode) PE11 is disposed to correspondto the color pixel PX11, and is connected to a source line S1 via aswitching element which is connected to the gate line G1. A pixelelectrode (second pixel electrode) PE12 is disposed to correspond to thecolor pixel PX12 and neighbors the pixel electrode PE11 in the firstdirection X. The pixel electrode PE12 is connected to a source line S2via a switching element which is connected to the gate line G1. A pixelelectrode (third pixel electrode) PE13 is disposed to correspond to thecolor pixel PX13 and neighbors the pixel electrode PE12 in the firstdirection X. The pixel electrode PE13 is connected to a source line S3via a switching element which is connected to the gate line G1.

A pixel electrode (fourth pixel electrode) PE14 is disposed tocorrespond to the color pixel PX14 and neighbors the pixel electrodePE11 in the second direction Y. The pixel electrode PE14 is connected tothe source line S1 via a switching element which is connected to a gateline G2. A pixel electrode (fifth pixel electrode) PE15 is disposed tocorrespond to the color pixel PX15 and neighbors the pixel electrodePE12 in the second direction Y. The pixel electrode PE15 is connected tothe source line S2 via a switching element which is connected to thegate line G2. A pixel electrode (sixth pixel electrode) PE16 is disposedto correspond to the color pixel PX16 and neighbors the pixel electrodePE13 in the second direction Y. The pixel electrode PE16 is connected tothe source line S3 via a switching element which is connected to thegate line G2.

Each of the pixel electrode PE11, pixel electrode PE12, pixel electrodePE14 and pixel electrode PE15 has a long-side length L11 in the seconddirection Y. The pixel electrode PE13 has a long-side length L12 in thesecond direction Y, which is greater than the long-side length L11. Thepixel electrode PE16 has a long-side length L13 in the second directionY, which is less than the long-side length L11.

Each of the pixel electrode PE11, pixel electrode PE12, pixel electrodePE14 and pixel electrode PE15 has a short-side length S11 in the firstdirection X. Each of the pixel electrode PE13 and pixel electrode PE16has a short-side length S12 in the first, direction X, which is greaterthan the short-side length S11.

The pixel electrode PE11 and pixel electrode PE14 arranged in the seconddirection Y are opposed to the color filter 32R shown in FIG. 5. Thepixel electrode PE12 and pixel electrode PE15 arranged in the seconddirection Y are opposed to the color filter 32G shown in FIG. 5. Thepixel electrode PE13 is opposed to the color filter 32B shown in FIG. 5.The pixel electrode PE16 is opposed to the color filter 32W shown inFIG. 5.

In this structure, the pixel electrode PE11, pixel electrode PE12, pixelelectrode PE14 and pixel electrode PE15 are substantially equal in area.The pixel electrode PE13 has a larger area than the pixel electrodePE16. In addition, the area of the pixel electrode PE13 is greater thanthe area of the pixel electrode PE11, etc., and is largest in the unitpixel UP1. The area of the pixel electrode PE16 is less than the area ofthe pixel electrode PE11, etc., and is smallest in the unit pixel UP1.

The short side of the pixel electrode PE11 and the short side of thepixel electrode PE12 extend on the same straight line which is parallelto the first direction X, but the short side of the pixel electrode PE13extends on an outside from each of the short sides of the pixelelectrode PE11 and pixel electrode PE12, that is, extends on a side awayfrom the gate line G1. In addition, the short side of the pixelelectrode PE14 and the short side of the pixel electrode PE15 extend onthe same straight line which is parallel to the first direction X, butthe short side of the pixel electrode PE16 extends on an inside fromeach of the short sides of the pixel electrode PE14 and pixel electrodePE15, that is, extends on a side closer to the gate line G2.

Incidentally, the pixel electrode PE21 is disposed to correspond to thecolor pixel PX21, the pixel electrode PE22 is disposed to correspond tothe color pixel PX22, the pixel electrode PE23 is disposed to correspondto the color pixel PX23, the pixel electrode PE24 is disposed tocorrespond to the color pixel PX24, the pixel electrode PE25 is disposedto correspond to the color pixel PX25, and the pixel electrode PE26 isdisposed to correspond to the color pixel PX26.

The pixel electrode PE21 and pixel electrode PS24 are opposed to thecolor filter 32R. The pixel electrode PE22 and pixel electrode PE25 areopposed to the color filter 32G. The pixel electrode PE23 is opposed tothe color filter 32W. The pixel electrode PE26 is opposed to the colorfilter 32B.

FIG. 7 is a plan view which schematically illustrates a structureexample of the second common electrode CE2 which is disposed to beopposed to the array substrate AR shown in FIG. 6.

The second common electrode CE2 is opposed to the pixel electrodes PE11to PE16 and the pixel electrodes PE21 to PE26. Slits SL are formed inthe second common electrode CE2 at positions opposed to the pixelelectrodes PE11 to PE16 and the pixel electrodes PE21 to PE26. The slitsSL have substantially the same shape. In the example illustrated, eachslit SL has a vertically elongated shape extending in the seconddirection Y.

Next, the operation of the display device in the embodiment isdescribed.

In an OFF state in which no potential difference is produced between thepixel electrode PE and the first, coupon electrode CE1 and second commonelectrode CE2 (i.e. a state in which no voltage is applied to the liquidcrystal layer LQ), no electric field is produced between the pixelelectrode PE and second common electrode CE2. Thus, as illustrated inFIG. 4, liquid crystal molecules LM included in the liquid crystal layerLQ are initially aligned substantially perpendicular to the substratemajor surface (X-Y plane) between the first vertical alignment film AL1and second vertical alignment film AL2. At this time, part of linearlypolarised light from the backlight unit BL passes through the firstpolarizer PL1 and enters the liquid crystal display panel LPN. Thepolarization state of the linearly polarized light, which enters theliquid crystal display panel LPN, hardly varies when the light passesthrough the liquid crystal layer LQ. Thus, the linearly polarized lightemerging from the liquid crystal display panel LPN is absorbed by thesecond polarizer PL2 that is in the positional relationship of crossed.Nicols in relation to the first polarizer PL1 (black display).

In an ON state in which a potential difference is produced between thepixel electrode PE and the first common electrode CE1 and second commonelectrode CE2 (i.e. a state in which a voltage is applied to the liquidcrystal layer LQ), a vertical electric field or an inclined electricfield avoiding the slits SL is produced between the pixel electrode PEand second caramon electrode CE2. Thus, the liquid crystal molecules LMare aligned in a direction different from the initial alignmentdirection, by the effect of the vertical electric field or inclinedelectric field. Specifically, since negative-type liquid crystalmolecules LM are aligned such that their major axes cross the electricfield, the liquid crystal molecules LM are aligned in the ON state in anoblique direction or in a horizontal direction, relative to thesubstrate major surface.

In this ON state, the polarization state of the linearly polarizedlight, which enters the liquid crystal display panel LPN, variesdepending on the alignment state of the liquid crystal molecules LM (orthe retardation of the liquid crystal layer) when the light passesthrough the liquid crystal layer LQ. Thus, in the ON state, at leastpart of the light emerging from the liquid crystal layer LQ passesthrough the second polarizer PL2 (white display).

In addition, in the ON state, a storage capacitance CS is formed by thepixel electrode PE and the first common electrode CE1 chat, are opposedto each other via the fourth insulation film 14, and retains a necessarycapacitance for displaying an image. Specifically, a pixel potential,which has been written in each pixel via the switching element SW, isretained in the storage capacitance CS for a predetermined period.

In the meantime, in the embodiment, the case of the linear polarizationmode has been exemplarily illustrated. However, the embodiment is alsoapplicable to a structure of a so-called circular polarization mode, inwhich a ¼ wavelength plate is inserted between each of the linearpolarizers provided on the front and back sides of the liquid crystaldisplay panel LPN, and the liquid crystal display panel LPN.

According to the present embodiment, the unit pixel is composed of sixcolor pixels of 2 rows×3 columns, four of the six color pixels have anequal pixel size, one of the other two color pixels has a largest pixelsize, and the other of the other two color pixels has a smallest pixelsize. Each of these six color pixels is allocated to any one of a redpixel, a green pixel, a blue pixel, and a white pixel. Two color pixelsin an identical column are allocated as red pixels. Two color pixels inan identical column are allocated as green pixels. A color pixel of thelargest pixel size is allocated as a blue pixel, and a color pixel ofthe smallest pixel sloe is allocated as a white pixel. The blue pixel islocated in the same column as the white pixel.

Thus, although color pixels of four columns need to be driven in a unitpixel configuration in which four color pixels of a red pixel, a greenpixel, a blue pixel and a white pixel are arranged in the firstdirection, it should suffice to drive color pixels of three columns inthe unit pixel configuration of the present embodiment, and an increasein power consumption can be suppressed.

In addition, since the number of color pixels arranged in the firstdirection is three, the restriction to the pitch in the first directionof color pixels constituting the unit pixel can be relaxed, compared tothe case in which the number of color pixels arranged in the firstdirection is four. Thus, even in the case where the length in the firstdirection of the unit pixel has decreased because of a demand for higherfineness, the length in the first direction of each color pixel can beset with an allowance, compared to the processing limit.

Furthermore, since the pixel size of the blue pixel can be freely set bythe short-side length in the first direction and the long-side length inthe second direction, the pixel size of the blue pixel can properly beset in accordance with the pixel size or transmittance of each of thered pixels and green pixels. Therefore, optimal color reproducibilitycan be realized.

Besides, the pixel size of the white pixel can also be freely set by theshort-side length in the first direction and the long-side length in thesecond direction. Thus, the display luminance of the white pixel can befreely set in a range lower than the total luminance of the red pixel,green pixel and blue pixel, and a higher luminance can be realizedwithout degrading the color reproducibility. In addition, bysubstituting the display luminance of the white pixel for the whitedisplay luminance produced by the red pixel, green pixel and blue pixel,the display luminance in the unit pixel increases. Thus, the luminanceof the backlight unit can be reduced by that degree, and the powerconsumption can be reduced. Furthermore, by virtue of the high luminanceof the unit pixel, the visibility of a display image can be enhancedeven in ambient light. In addition, since the pixel size of the whitepixel does not excessively increase, the white pixel itself is lesseasily visually recognized even when an image with a high displayluminance is displayed by the white pixel. Therefore, the displayquality can be improved.

According to the embodiment, the capacitance, which is necessary fordisplaying an image in each pixel, can be formed by the pixel electrodePE and first common electrode CE1 which are opposed via the fourthinsulation film 14. Thus, when the capacitance is formed, a wiring lineor electrode, which crosses the pixel and is formed of a light-shieldingwiring material, is needless. In addition, the fourth insulation film 14is formed to have a smaller film thickness than the third insulationfilm that is formed of a resin material or the like. Therefore, arelatively large capacitance can easily be formed by the pixel electrodePE and first common electrode CE1 which are disposed via the fourthinsulation film 14.

Moreover, since each of the pixel electrode PE and first commonelectrode CE1 is formed of a transparent, electrically conductivematerial, an area overlapping the pixel electrode PE and first commonelectrode CE1 contributes to display. Thus, compared to a comparativeexample in which a storage capacitance line crossing the pixel isdisposed, the aperture ratio, transmittance or luminance per pixel,which contributes to display, can be improved. Therefore, while thecapacitance necessary for display is secured, the display quality can beimproved.

In addition, the first common electrode CE1 extends above the sourceline S1 and source line S2. Thus, in the on state, an undesired leakelectric field from the source line toward the liquid crystal layer LQcan be shielded by the first common electrode CE1. Specifically, it ispossible to suppress formation of an undesired electric field or anundesired capacitance between the source line and the pixel electrode PEor second common electrode CE2, and to suppress disturbance in alignmentof liquid crystal molecules LM in an area overlapping the source line.

Furthermore, the liquid crystal molecules LM in the area overlapping thesource line maintains the initial alignment state even in the ON state,since the first common electrode CE1 and second common electrode CE2 arekept at the same potential. Therefore, pixel electrodes PE neighboringin the first direction X can be located closer to each other up to aprocessing limit, and the area which contributes to display per pixelcan further be increased.

Besides, even when one of the pixels neighboring with the source lineinterposed is in the ON state and the other is in the OFF state, thereis no potential difference, by the first common electrode CE1 and secondcommon electrode CE2, in the liquid crystal layer on the source linebetween the ON-state pixel and OFF-state pixel. Thus, the liquid crystalmolecules LM in the area overlapping the source line are kept in theinitial alignment state. Therefore, even when the liquid crystal displaypanel LPN is viewed in an oblique direction, degradation in displayquality due to color mixing can be suppressed. In addition, since thereis no need to increase the width of the light-shield layer 31 in orderto prevent color mixing, the area contributing to display per pixel canfurther be increased.

Next, modifications will be described.

FIG. 3 is a plan view which schematically illustrates another structureexample of the array substrate AR which is applicable to the displaydevice of the embodiment.

The structure example illustrated in FIG. 8 differs from the arraysubstrate AR of FIG. 6 in that the unit pixel adopts a rectangularlayout.

The gate line G1 extends in the first direction X and is located atupper end portions of the color pixel PX11, color pixel PX12, colorpixel PX13, color pixel PX21, color pixel PX22 and color pixel PX23. Thegate line G2 extends in the first direction X and is located at lowerend portions of the color pixel PX14, color pixel PX15, color pixelPX16, color pixel PX24, color pixel PX25 and color pixel PX26. The unitpixel UP1 end unit pixel UP2 have the same shape, and each of the unit,pixel UP1 and unit pixel UP2 has a rectangular shape with a pair ofshort sides in the first direction X and a pair of long sides in thesecond direction Y.

One of the short sides of the unit pixel UP1 is formed by a short sideof the color pixel PX11, a short side of the color pixel PX12 and ashort side of the pixel PX13, which extend on the same straight line.The other of the short sides of the unit pixel UP1 is formed by a shortside of the color pixel PX14, a short side of the color pixel PX15 and ashort side of the pixel PX16, which extend on the same straight line.

In the unit pixel UP1, the pixel electrode PE11 is disposed tocorrespond to the color pixel PX11, the pixel electrode PE12 is disposedto correspond to the color pixel PX12, the pixel electrode PE13 isdisposed to correspond to the color pixel PX13, the pixel electrode PE14is disposed to correspond to the color pixel PX14, the pixel electrodePE15 is disposed to correspond to the color pixel PX15, and the pixelelectrode PE16 is disposed to correspond to the color pixel PX16. Thepixel electrode PE11 and pixel electrode PE14 are opposed to the colorfilter 32R, the pixel electrode PE12 and pixel electrode PE15 areopposed to the color filter 32G, the pixel electrode PE13 is opposed tothe color filter 32B, and the pixel electrode PE16 is opposed to thecolor filter 32W.

One of the short sides of the unit pixel UP2 is formed by a short sideof the color pixel PX21, a short side of the color pixel PX22 and ashort side of the pixel PX23, which extend on the same straight line.The other of the short sides of the unit pixel UP2 is formed by a shortside of the color pixel PX24, a short, side of the color pixel PX25 anda short side of the pixel PX26, which extend on the same straight line.

In the unit pixel UP2, the pixel electrode PE21 is disposed tocorrespond to the color pixel PX21, the pixel electrode PE22 is disposedto correspond to the color pixel PX22, the pixel electrode PE23 isdisposed to correspond to the color pixel PX23, the pixel electrode PE24is disposed to correspond to the color pixel PX24, the pixel electrodePE25 is disposed to correspond to the color pixel PX25, and the pixelelectrode PE26 is disposed to correspond to the color pixel PX26. Thepixel electrode PE21 and pixel electrode PE24 are opposed to the colorfilter 32R, the pixel electrode PE22 and pixel electrode PE25 areopposed to the color filter 32G, the pixel electrode PE23 is opposed tothe color filter 32W, and the pixel electrode PE26 is opposed to thecolor filter 32B.

In this structure, example, too, the same advantageous effects as in theabove-described example can be obtained.

FIG. 9 is a plan view which schematically illustrates another structureexample of the array substrate AR which is applicable to the displaydevice of the embodiment.

The structure example illustrated in FIG. 9 differs from the arraysubstrate AR of FIG. 6 in which the vertical electric field mode isadopted, in that a transverse electric field mode is adopted.

Slits SL are formed in the pixel electrodes PE11 to PE16 and pixelelectrodes PE21 to PE26, which overlap the common electrode CE. In theexample illustrated, each slit SL is formed in a linear shape extendingin the second direction Y, but the shape is not limited to thisillustrated example. This array substrate AR can be combined with thecounter-substrate including the color filters of the layout shown inFIG. 5. Incidentally, the counter-substrate including the second commonelectrode CE2 as shown in FIG. 7 is needless.

In this structure example, too, the same advantageous effects as in theabove-described example can be obtained.

As has been described above, according to the present embodiment, adisplay device, which can improve display quality, can be provided.

In the meantime, in the above-described embodiments, the liquid crystaldisplay device has been described as the display device, but the displaydevice may be an organic EL display device. Specifically, instead ofusing the respective color filters shown in FIG. 5, the respective pixelelectrodes shown in FIG. 6 may be replaced with light emission portionsof organic EL elements. An organic EL element which emits red light isdisposed in the red pixel, an organic EL element which emits green lightis disposed in the green pixel, an organic SL element which emits bluelight is disposed in the blue pixel, and an organic EL element whichemits white light is disposed in the white pixel. In this structure,too, the layout as illustrated in FIG. 5 and FIG. 6 may be adopted.Thereby, the sizes of the blue organic EL element and white organic ELelement can be freely set, and the same advantageous effects as in theabove-described embodiments can be obtained.

While certain embodiments have been described, these embodiments havebeen presented by way of example only, and are not intended to limit thescope of the inventions. Indeed, the novel embodiments described hereinmay be embodied in a variety of other forms; furthermore, variousomissions, substitutions and changes in the form of the embodimentsdescribed herein may be made without departing from the spirit of theinventions. The accompanying claims and their equivalents are intendedto cover such forms or modifications as would fall within the scope andspirit of the inventions.

What is claimed is:
 1. A display device comprising: an array substrateincluding a first pixel electrode, a second pixel electrode neighboringthe first pixel electrode in a first direction, a third pixel electrodeneighboring the second pixel electrode in the first direction, a fourthpixel electrode neighboring the first pixel electrode in a seconddirection intersecting the first direction, a fifth pixel electrodeneighboring the second pixel electrode in the second direction andneighboring the fourth pixel electrode in the first direction, a sixthpixel electrode neighboring the third pixel electrode in the seconddirection and neighboring the fifth pixel electrode in the firstdirection, a common electrode opposed to the first to sixth pixelelectrodes, and an insulation film between the common electrode and thefirst to sixth pixel electrodes, wherein each of the first to sixthpixel electrodes has a plurality of main pixel electrodes and aconnecting part connecting the plurality of main pixel electrodes, atleast one of the plurality of main pixel electrodes of the third pixelelectrode is longer than the plurality of main pixel electrodes of thefirst and second pixel electrodes in the second direction, at least oneof the plurality of main pixel electrodes of the sixth pixel electrodeis shorter than the plurality of main pixel electrodes of the fourth andfifth pixel electrodes, the plurality of main pixel electrodes of thefirst pixel electrode, the plurality of main pixel electrodes of thesecond pixel electrode, the plurality of main pixel electrodes of thefourth pixel electrode, and the plurality of main pixel electrodes ofthe fifth pixel electrode have substantially the same length, theconnecting part of the first pixel electrode and the connecting part ofthe second pixel electrode extend on a first straight line, theconnecting part of the third pixel electrode extends on a secondstraight line, the second straight line is shifted in the seconddirection from the first straight line, the connecting part of thefourth pixel electrode and the connecting part of the fifth pixelelectrode extend on a third straight line, the connecting part of thesixth pixel electrode extends on a fourth straight line, the fourthstraight line is shifted in the second direction from the third straightline, a number of the plurality of main pixel electrodes of the thirdpixel electrode is greater than a number of the plurality of main pixelelectrodes of the first and the second pixel electrodes, a number of theplurality of main pixel electrodes of the sixth pixel electrode isgreater than a number of the plurality of main pixel electrodes of thefourth and the fifth pixel electrode, the number of the plurality ofmain pixel electrodes of the first pixel electrode, the number of theplurality of main pixel electrodes of the second pixel electrode, thenumber of the plurality of main pixel electrodes of the fourth pixelelectrode and the number of the plurality of main pixel electrodes ofthe fifth pixel electrode are the same, and the number of the pluralityof main pixel electrodes of the third pixel electrode is the same as thenumber of the plurality of main pixel electrodes of the sixth pixelelectrode.
 2. The display device of claim 1, wherein the array substratefurther includes a first gate line and a second gate line, the firstgate line is electrically connected to the first to third pixelelectrodes, the second gate line is electrically connected to the fourthto sixth pixel electrodes, the first gate line crosses central portionsof the second direction of the first to third pixel electrodes,respectively, and the second gate line crosses central portions of thesecond direction of the fourth to sixth pixel electrodes, respectively.3. A display device comprising: a first substrate including a firstpixel electrode, a second pixel electrode neighboring the first pixelelectrode in a first direction, a third pixel electrode neighboring thesecond pixel electrode in the first direction, a fourth pixel electrodeneighboring the first pixel electrode in a second direction, a fifthpixel electrode neighboring the second pixel electrode in the seconddirection, a sixth pixel electrode neighboring the third pixel electrodein the second direction, a first common electrode, an interlayerinsulation film covering the first common electrode, and a firstalignment film covering the first to sixth pixel electrodes; a secondsubstrate including a first color filter extending in the seconddirection and opposed to the first pixel electrode and the fourth pixelelectrode, a second color filter neighboring the first color filter inthe first direction, extending in the second direction and opposed tothe second pixel electrode and the fifth pixel electrode, a third colorfilter neighboring the second color filter in the first direction andopposed to the third pixel electrode, a fourth color filter neighboringthe third color filter in the second direction and opposed to the sixthpixel electrode, and a second alignment film; and a liquid crystal layerheld between the first substrate and the second substrate, wherein thefirst to sixth pixel electrodes are formed on the interlayer insulationfilm and are opposed to the first common electrode, each of the firstpixel electrode, the second pixel electrode, the fourth pixel electrode,and the fifth pixel electrode has a first main pixel electrode extendingin the second direction, the third pixel electrode has a second mainpixel electrode which extends in the second direction and is larger thanthe first main pixel electrode, and the sixth pixel electrode has athird main pixel electrode which extends in the second direction and issmaller than the first main pixel electrode, the first pixel electrodehas a first edge and a second edge, the second pixel electrode has athird edge and a fourth edge, each of the first to fourth edge extendsin the first direction, the first edge and the third edge extend on afirst straight line, the second edge and the fourth edge extend on asecond straight line, and the third pixel electrode has a fifth edgewhich is displaced in the second direction from the first straight lineand a sixth edge which is displaced in the second direction from thesecond straight line.